Alpha decay
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Alpha decay (a.k.a. α decay) is the radioactive process in which an alpha (α) particle (containing two neutrons and two protons) is ejected from the nucleus. An alpha particle is identical to the nucleus of a helium atom. All nuclei with the atomic number (Z) greater than 82, are considered unstable. These are considered “neutron-rich” and undergo alpha decay commonly.
Alpha decay occurs in the nuclei of heavy elements, like radium, uranium, thorium, etc. When a nucleus of Ra (radium) decays, it emits an alpha particle and becomes an Rn (radon) nucleus. In general, during alpha decay, the atomic number (Z) is reduced by two, and the mass number (A), by four. For example, alpha decay generates Rn-222 with atomic number 86 and the mass number 222 from Ra-226 with the atomic number 88 and the mass number 226.
Alpha particles are very heavy and contain high amounts of energy (4-10 MeV). Their speed is ~20000km~20000 km/s and they interact with matter, causing much ionisation over a very short distance. They usually pass short distances (a 5 MeV alpha particle will travel about 20 micrometres in silicon) and can be stopped by a sheet of paper. Alpha particles do not produce Bremsstrahlung radiation when slowing down.
Alpha particles are not generally dangerous unless the source is ingested or inhaled since alpha radiation is the most destructive form of ionising radiation.
Historically, radium and radon were the principal alpha emitters of medical interest. Radium-223 dichloride is still used today in treating osseous metastases. Other alpha emitters are being researched for therapeutic approaches using radiopharmaceuticals that can target the delivery of short half-life alpha emitters into cancerous cells. Due to their very short range, alpha particles have the potential to deliver a lethal radiation dose to small metastatic cell clusters, while mostly sparing the surrounding tissue. All work with alpha emitters must be conducted under very strictly controlled conditions.
See also
-<p><strong>Alpha decay</strong> is the process in which an alpha particle (containing two neutrons and two protons) is ejected from the nucleus. An alpha particle is identical to the nucleus of a helium atom. All nuclei with the atomic number (Z) greater than 82, are considered unstable. These are considered “neutron-rich” and undergo alpha decay commonly.</p><p>Alpha decay occurs in the nuclei of heavy elements, like radium, uranium, thorium etc. When a nucleus of Ra (radium) decays, it emits an alpha particle and becomes an Rn (radon) nucleus. In general, during alpha decay, the atomic number (Z) is reduced by two, and the mass number (A), by four. For example, alpha decay generates Rn-222 with atomic number 86 and the mass number 222 from Ra-226 with the atomic number 88 and the mass number 226.</p><p>Alpha particles are very heavy and contain high amounts of energy (4-10 MeV). Their speed is ~20000km/s and they interact with matter, causing much ionisation over a very short distance. They usually pass short distances (a 5 MeV alpha particle will travel about 20 micrometres in silicon) and can be stopped by a sheet of paper. Alpha particles do not produce <a href="/articles/bremsstrahlung">Bremsstrahlung radiation</a> when slowing down.</p><p>Alpha particles are not generally dangerous unless the source is ingested or inhaled since alpha radiation is the most destructive form of ionising radiation.</p><p>Historically, radium and radon were the principal alpha emitters of medical interest. Radium-223 dichloride is still used today in treating osseous metastases. Other alpha emitters are being researched for therapeutic approaches using radiopharmaceuticals that can target the delivery of short half-life alpha emitters into cancerous cells. Due to their very short range, alpha particles have the potential to deliver a lethal radiation dose to small metastatic cell clusters, while mostly sparing the surrounding tissue. All work with alpha emitters must be conducted under very strictly controlled conditions.</p><h4>See also</h4><ul><li><a href="/articles/beta-decay">beta decay</a></li></ul>- +<p><strong>Alpha decay</strong> (a.k.a. <strong>α decay</strong>) is the <a href="/articles/radioactivity">radioactive process</a> in which an alpha (α) particle (containing two neutrons and two protons) is ejected from the nucleus. An alpha particle is identical to the nucleus of a <a href="/articles/helium">helium</a> atom. All nuclei with the atomic number (Z) greater than 82, are considered unstable. These are considered “neutron-rich” and undergo alpha decay commonly.</p><p>Alpha decay occurs in the nuclei of heavy elements, like radium, uranium, thorium, etc. When a nucleus of Ra (radium) decays, it emits an alpha particle and becomes an Rn (radon) nucleus. In general, during alpha decay, the atomic number (Z) is reduced by two, and the mass number (A), by four. For example, alpha decay generates Rn-222 with atomic number 86 and the mass number 222 from Ra-226 with the atomic number 88 and the mass number 226.</p><p>Alpha particles are very heavy and contain high amounts of energy (4-10 <a href="/articles/electronvolt-unit">MeV</a>). Their speed is ~20000 km/s and they interact with matter, causing much <a href="/articles/ionisation">ionisation</a> over a very short distance. They usually pass short distances (a 5 MeV alpha particle will travel about 20 micrometres in silicon) and can be stopped by a sheet of paper. Alpha particles do not produce <a href="/articles/bremsstrahlung-radiation">Bremsstrahlung radiation</a> when slowing down.</p><p>Alpha particles are not generally dangerous unless the source is ingested or inhaled since alpha radiation is the most destructive form of ionising radiation.</p><p>Historically, radium and radon were the principal alpha emitters of medical interest. Radium-223 dichloride is still used today in treating osseous metastases. Other alpha emitters are being researched for therapeutic approaches using radiopharmaceuticals that can target the delivery of short half-life alpha emitters into cancerous cells. Due to their very short range, alpha particles have the potential to deliver a lethal radiation dose to small metastatic cell clusters, while mostly sparing the surrounding tissue. All work with alpha emitters must be conducted under very strictly controlled conditions.</p><h4>See also</h4><ul>
- +<li><a href="/articles/beta-decay">beta decay</a></li>
- +<li><a href="/articles/gamma-decay">gamma decay</a></li>
- +</ul>
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